The present invention generally relates to rotary motors, and more particularly, to piezoelectric ultrasonic rotary motor systems which may include an attached unbalanced mass that generates an oscillating centripetal force perpendicular to an axis of rotation for use as a haptic actuator and methods thereof.
Haptic actuators are devices that generate vibrations that can be felt by a person. Haptic actuators have become increasingly important in applications in handheld devices, such as cellphones and smartphones. Additional background information about haptic actuators is disclosed in U.S. Patent Application Publication No. 2011/0241851 to Henderson et al., which is herein incorporated by reference in its entirety.
However, there are some limitations to the maximum reaction force that prior art haptic actuators can produce in practical applications. In particular, the dynamic force (for a small size motor and/or moderate driven power) may not be sufficient to accelerate the entire mobile phone handset and create vibrations that are perceived by the user.
When a motor of small size (e.g., 6 mm in length and up to 2 mm in diameter) is subject to a force of about 20 grams of force (20 gf) at the node points (points on the motor that have the lowest vibration amplitude for a first bending mode vibration), the vibration amplitude of the motor begins to be dampened, and the maximum rotation speed of the shaft begins to decrease. Since the centripetal force is about 0.63 N (over 60 gf) for 200 Hz rotation of a typical rotating (Tungsten) mass of 0.4 grams offset about 1 mm from the centreline of the shaft rotation, and it acts upon antinode points of the motor (both ends or center which have the highest vibration amplitudes for a first bending mode vibration), this centripetal force will dampen the motor vibration even more than the 20 gf preload force at the node points of the motor. Thus, the maximum rotation speed of the shaft is limited (much below 200 Hz) and the resulting centripetal force is not sufficient for many applications.
Another potential limitation for the maximum reaction force is due to the way the motor is mounted. In the prior art, the motor is typically compliantly secured to a housing at the node points by an elastomer material, such as silicone. Unfortunately, the compliance of this mounting method will degrade the transmission of the centripetal force from the rotating unbalanced mass through the motor and then to the housing.
A rotary motor includes a vibrating motor body which has two orthogonal first bending modes and is substantially enclosed within a housing. A shaft is frictionally coupled to the vibrating motor body and is arranged to rotate in at least one direction about a rotation axis in response to the vibrating motor body. The shaft is frictionally coupled the vibrating motor body by a force substantially perpendicular to the rotation axis. One or more bearings support the shaft, are connected to the housing, and define the axis of rotation of the shaft.
A method of making a rotary motor includes providing a vibrating motor body which has two orthogonal first bending modes and is substantially enclosed within a housing. A shaft is frictionally coupled to the vibrating motor body by applying a force substantially perpendicular to the rotation axis. The shaft is arranged to rotate in at least one direction about a rotation axis in response to the vibrating motor body. One or more bearings are provided that support the shaft, are connected to the housing, and define the axis of rotation of the shaft.
This exemplary technology provides a number of advantages including providing more effective and efficient piezoelectric ultrasonic rotary motor apparatuses and methods. For example, this technology achieves a significant decrease in the dampening of the motor body and thus high vibration amplitude of the motor body and a high rotation speed of the shaft. Additionally, this technology reduces drag and system volume/length, as well as reducing stress inside the shaft during drop testing.
An exemplary rotary motor system 100 is illustrated in
Referring to
Referring again to
Referring again to
Referring now to
The main body 116a is bonded to a pair of piezoelectric plates 144a and 144b, although the main body 116a may be attached to other numbers and types of piezoelectric elements at different locations. In this example, the piezoelectric plates 144a and 144b are co-fired multilayer devices, although other piezoelectric plates, such as single layer piezoelectric plates may be used. The piezoelectric plates 144a and 144b are bonded to the main body 116a using high strength adhesive, although other suitable bonding techniques may be used. Further explanation of piezoelectric ceramic materials and how they are used to generate ultrasonic vibrations is contained in U.S. Pat. No. 8,217,553, which is herein incorporated by reference in its entirety.
Referring to
Referring to
The main body 116a includes notches 118a and 118b which are located at node points of the main body 116a, as illustrated in
Referring now to
Referring again to
In the exemplary embodiment shown in
In this example, the unbalanced masses 132a and 132b are attached to the shaft 124 through a crimp/press fit, although the masses can be attached in other manners, such as with a high strength adhesive by way of example only. In this example, the unbalanced masses 132a and 132b include wrap-around or cantilevered portions 134a and 134b, although the unbalanced masses may have other shapes and configurations. The cantilevered portions 134a and 134b reduce the actuator length along the motor axis and the actuator volume while the mr product is fixed.
Bearings 136a and 136b are pressed into the ends of tubular cage 102 and serve as a guide for the rotating shaft 124, as shown in
The configuration of the mount 104, the tubular cage 102 and the mounting holes 106a and 106b is designed to solidly connect bearings 136a and 136b to a target device (not shown), such as a mobile phone by way of example only. In this example, cantilevered portions 134a and 134b of the unbalanced masses 132a and 132b, respectively, bring the center of gravity for each mass 138a and 138b inside the bearings 136 and significantly lower the stress inside the shaft 124 during drop testing. It is to be understood that the cantilevered portions 134a and 134b are optional and that different designs with different functions may be utilized.
Washers 140a and 140b are secured in between the tubular motor body 116 and the bearings 136a and 136b, respectively and washers 142a and 142b are secured in between the unbalanced masses 132a and 132b and the bearings 136a and 136b, respectively, although other friction reducing elements may be used. In this example, washers 140a and 140b and 142a and 142b are made of relatively soft and low friction material, such as plastics, although the washers may be made of any other suitable material.
In one example, the rotary motor system 100 includes an optional rotational speed sensor 150, as illustrated in
An exemplary operation of the rotary motor system 100 of the present invention will now be described with reference to
When voltage signals are applied between the electrodes 146a and 146b of piezoelectric plate 144a and electrodes 146c and 146d of piezoelectric plate 144b, the length of piezoelectric plates 144a and 144b changes. The changes in length of the piezoelectric plates 144a and 144b bends the main body 116a. When the two ultrasonic signals are driven at the first order bending resonant frequency of the tubular motor body 116 and their phase difference is approximately 90 degrees, the tubular motor body 116 will be excited into a “hula-hoop” vibration in this example, which will further cause the shaft 124 to rotate in at least one direction. The tubular motor body 116 drives the shaft 124 at drive sections 128a and 128b where the corresponding vibration amplitude of tubular motor body 116 is at a maximum (antinode points).
The rotational output of the rotary motor system 100 is through the shaft 124. The rotary motor system 100 may be coupled to a device at any point, or a combination of points, along the shaft 124, such as one or both ends of the shaft 124, or somewhere in the middle of the shaft 124. The rotational output of the shaft 124 may be used for various purposes. By way of example only, the rotational output of the shaft 124 may be used to rotate a mirror, a prism, a medical device, a lead screw, or unbalanced masses, such as 132a and 132b, although the rotational output may be used for other types and numbers of purposes.
In the embodiment shown in
During operation, the node points on the tubular motor body 116 have the least amount of motion during vibration. Preloading the spring 120 at notches 118a and 118b, which are located at the node points of the tubular motor body 116 decreases the amount of interference/damping to the vibration of the rotary motor system 100. The notches 118a and 118b also prevent the preload spring 120 from moving away from or slipping from the node points during operation of the rotary motor system 100.
Spring 120 is preloaded with a force of approximately 15 to 20 gf, which is approximately equally distributed to drive sections 128a and 128b. The reaction forces at drive sections 128a and 128b can generate enough starting (frictional) drive force or torque to overcome the eccentric gravity of the unbalanced masses 132a and 132b and also accelerate it fast enough to meet the spin up time requirement (the rotary motor system 100 is required to reach a certain rotational speed at a specified amount of time).
Referring to
Rotary motor system 400 has a single unbalanced mass 432 attached to the shaft 424, although other elements in other numbers and configurations may be attached to shaft 424. In this example, unbalanced mass 432 is attached to the shaft 424 through a crimp/press fit, although the mass can be attached in other manners, such as with a high strength adhesive by way of example only. In this example, the single unbalanced mass 432 is larger than the unbalanced masses shown attached to rotary motor system 100 shown in
Rotary motor system 400 has a shaft stop or snap ring 450 clamped on the end of shaft 424 opposite the single unbalanced mass 432, although other numbers and types of elements may be clamped on the shaft 424 at different locations along the shaft.
Bearings 436a and 436b serve as guides for the rotating shaft 424, although other types and numbers of guides for the shaft 424 can be used. The bearings 436a and 436b may be simple journal bearings, which may be made of various materials, including oilite bearing material (oilite bronze), bronze, or plastics by way of example only, although the bearings 436a and 436b may be other types of bearings, such as ball bearings by way of example only. In this example, bearing 436a has an increased width to support the necessary drop test requirements, while bearing 436b is designed slightly narrower due to the decreased load, although bearings 436a and 436b may have other shapes and configurations.
In this example, the unbalanced mass 432 has a cantilevered design so that its center of gravity 438 is inside bearing 436a, which significantly lowers the stress inside the shaft during drop test (especially in the direction perpendicular to the motor axis Z), although the unbalanced mass may be designed in other configurations.
As shown in
In this example, when the shaft 424 and the unbalanced mass 432 are driven to the maximum rotation speed, the centripetal force generated by the unbalanced mass 432 (attached to the rotating shaft 424, which is supported by bearings 436a and 436b) is transmitted through bearings 436a and 436b, the cage or housing 404, the mount 402, and finally to the targeted device (not shown), and hence a haptic feeling is generated.
Another embodiment of a rotary motor system 500 of the present invention is illustrated in
Rotary motor system 500 has a singled unbalanced mass 532 located between the two bearings 536a and 536b, although other numbers of unbalanced masses may be used in other locations. In this example, bearing 536a is pressed into a frame 552 and bearing 536b is pressed into cage or housing 502, which is joined with frame 552 by methods such as welding, although other methods of joining the cage 502 and frame 552 may be used. The center of gravity 538 of the unbalanced mass 532 is located outside the bearing 536a due to length limitations. In this example, bearing 536a is made wider to handle the increased load, although bearing 536a may have other shapes and configurations. Constrained by frame 552 and cage 502 in the motor axis Z, the bearings 536a and 536b cannot fall out in a drop test along the motor axis Z.
Rotary motor system 500 includes three thin washers 540a-c, although other numbers and types of friction reducing elements may be used to increase performance. Washer 540a separates bearing 536a and the unbalanced mass 532 and reduces drag to the rotating mass/shaft during actuator operation. Washer 540b separates the unbalanced mass 532 and the motor tube 516 and reduces friction and the dampening to the tubular motor body 516 during actuator operation. Washer 540c separates the tubular motor body 516 and bearing 536b and it also minimizes the friction and dampening to the tubular motor body 516.
As shown in
In this example, when the shaft 524 and the unbalanced mass 532 are driven to the maximum rotation speed, the centripetal force generated by the unbalanced mass 532 (attached to the rotating shaft 524, which is supported by bearings 536a and 536b) is transmitted through bearings 536a and 536b, the cage 502, the mount 504, and finally to the targeted device (not shown), and hence a haptic feeling is generated.
Another embodiment of a rotary motor system 600 of the present invention is illustrated in
Rotary motor system 600 includes two symmetric masses 632a and 632b, which do not include cantilevered or wrapped-around portions, although other numbers of unbalanced masses with different configurations may be used. In this example, the masses 632a and 632b have smaller diameters (compared with that of masses 232a and 232b in haptic actuator 200) and thus can drastically reduce the height profile of the whole haptic actuator or device.
As shown in
Accordingly, as illustrated and described with the examples herein provides more effective and efficient piezoelectric ultrasonic rotary motor apparatuses and methods. With this technology, high rotation speed, larger vibrational force, and longer life for the rotary motor system may be obtained.
Having thus described the basic concept of the invention, it will be rather apparent to those skilled in the art that the foregoing detailed disclosure is intended to be presented by way of example only, and is not limiting. Various alterations, improvements, and modifications will occur and are intended to those skilled in the art, though not expressly stated herein. These alterations, improvements, and modifications are intended to be suggested hereby, and are within the spirit and scope of the invention. Accordingly, the invention is limited only by the following claims and equivalents thereto.
This application claims the benefit of U.S. Provisional Application No. 61/693,665, filed Aug. 27, 2012 which is hereby incorporated by reference in its entirety.
Number | Name | Date | Kind |
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7309943 | Henderson et al. | Dec 2007 | B2 |
8217553 | Xu et al. | Jul 2012 | B2 |
20070029900 | Kang et al. | Feb 2007 | A1 |
20100247087 | Suzuki et al. | Sep 2010 | A1 |
20110241851 | Henderson et al. | Oct 2011 | A1 |
Number | Date | Country | |
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20140055004 A1 | Feb 2014 | US |
Number | Date | Country | |
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61693665 | Aug 2012 | US |